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Publication numberUS3114283 A
Publication typeGrant
Publication dateDec 17, 1963
Filing dateOct 31, 1960
Priority dateOct 31, 1960
Publication numberUS 3114283 A, US 3114283A, US-A-3114283, US3114283 A, US3114283A
InventorsHeinz E R Gruner
Original AssigneeBausch & Lomb
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Light sensing method and apparatus therefor
US 3114283 A
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Description  (OCR text may contain errors)

LIGHT SENSING METHOD AND APPARATUS THEREFOR Filed 001:. 31, 1960 mmvrox HEINZ E. R. GRUNER BY @EMPJ. W62

ATTORNEYS United States Patent 3,114,283 LIGHT SENSKNG METHOD AND APPARATUS THEREFOR Heinz E. R. Gruner, Irondequoit, N.Y., assignor to Bausch & Lomb Incorporated, Rochester, N.Y., a corporationof New York Filed Oct. 31, 1960, Ser. No. 66,044 2 Claims. (Cl. 88--24) This invention relates to a novel light sensing method and apparatus therefor, and more particularly to a method and apparatus for measuring light intensity in a photographic projector, or enlarger, for exposure control.

The method and devices of the. present invention are especially advantageous for use in automatic dodging in the back direction from the objective lens of a photographic enlarger, thereby providing an indication of the field illumination in the projector or enlarger during an exposure. The sensor output may be connected to any desired control circuit for automatically controlling the exposurewithout the need for preliminary readings. The

for contrast and exposure control in photographic enlargers of the type having a flying spot source of projection illumination. Previous automatic dodging arrangements for use in conjunction with enlargers of this typev have been proposed. See, for example, the

system described by Craig in US. Patent No. 2,842,025.

In this type of system it is diflicult to compensate for variations due to differences in the spacings between the photosensor and various different portions of the field traversed by the flying spot. It is also difiicult to arrange such a system for use when the projection is to be made upon an opaque surface. In such cases, the control must be by reflected light, and changes in the angle of incidence of the flying spot are apt to produce large variations in the control signal.

Parallax also presents a serious problem in dodging when using a cathode ray tube to generate the flying spot of light. A portion of the negative projected by the point light source lies along a line drawn from the point source to the center of the projection lens. Since the point light source is at a considerable distance from the negative being projected, a photosensor or transducer placed beside the lens and facing the negative, senses the point source through a different portion of the negative from the portion being projected.

The present invention provides a novel method and apparatus for measuring the light intensity of a projected image in a photographic enlarger, which overcomes to a high degree many of the disadvantages of previous methods and apparatus.

Accordingly, the method and apparatus described herein are elfective to minimize errors due to parallax, to compensate for over-or-under exposure, to modify the light intensity in response to changes of density between successive negative portions being projected, to control picture contrast, and to compensate for exposure variations due to picture shape distortion in rectification.

The method and devices of the present invention are particularly well suited for photogrammetric enlargers, or other enlargers of the type having a flying spot source of projection illumination, since they are relatively unaffected by variations in the reflected light intensity caused by the movement of the flying spot with respect to a curved projection lens.

The invention will now be described in detail in connection with the accompanying drawings, in which:

FIG. 1 is a schematic cross-sectional view of an enlarger and a light sensing device mounted therein including an array of optical pickup elements according to the invention;

FIG. 2 is a schematic plan view on an enlarged scale of the array of optical pickup elements shown in FIG. 1; and

FIG. 3 is an enlarged cross sectional view taken along the line 33 in FIG. 2.

In accordance with the method of the present invention, a photosensor is arranged to sense light reflected preferred method includes the step of sensing light reflected in'various different directions from the lens, and producing a signal indicative of the average intensity of the light reflected in the various different directions. The method provides a measure of the intensity of the light actually passing through the projection center of the enlarger, regardless of the direction from which it comes, thus minimizing errors due to differences caused by parallax, or by the illumination direction, andlens curvature. I I

Referring now to the drawing, which illustrates a preferred embodiment of the invention, a conventional photographic enlarger 2 of the type commonly used for photogrammetric rectification is shown therein. The enlarger 2 includes a cathode ray tube light source 4, a film holder 6, a lens board 8, and a projection lens 10 mounted on the lens board 8. An easel 12, a housing 14 and a bellows 16 are shown in their customary arrangement.

In accordance with the invention, a plurality of optional pickup elements 20 are angularly spaced around the periphery of the projection lens 10 in radial array facing the projection lens 10. The entrant faces 22, of the optical pickup elements facing the projection lens 10, are mounted in radial holes 24, in a ring 26, which is fixed to the lens board 8, coaxially with the lens 10. The faces of the optical pickup elements are recessed in the ring 26, so that the ring 26 acts as a light shield to limit the acceptance angles of the elements 20, and prevent direct rays from the light source 4 from entering the elements 20. It is desirable to have the optical paths between the pickup faces and the exit faces of equal lengths in order to equalize the light losses occurring within the individual elements.

The exit faces 28 of the optical pickup elements are fused together, or secured by the bands 35 to form a single bundle 32, the exit face 28 faces a photoelectric transducer 34 such as a photomultiplier vacuum tube. A field lens 36 may be disposed between the bundle 32 and the transducer 34 for maximizing the light signal transmitted to the transducer.

An amplifier 38 is connected between the output of the photomultiplier tube 34 and a control circuit 40. The control circuit 40 may be arranged to control the light intensity, illumination time, or aperture opening of the enlarger, or the scanning speed when used in an enlarger having a flying spot light source. The control circuit may be of any desired type, and does not per se constitute the present invention.

In operation of the enlarger, a portion of the field illumination is unavoidably reflected from the back surface of the projection lens. It is this reflected portion of the field illumination that is used in the practice of the invention to measure the total field illumination.

The reflected light enters the optical pickup elements 20 and is directed thereby to the common transducer 34. The transducer 34 produces an electrical signal for exposure control, which may be accomplished by varying the cathode ray tube intensity or scanning speed, or otherwise.

The array of optical pickup elements may be made of light transmitting rods such as Lucite, or other material which is capable of light transmission by total internal reflection. It is also contemplated that the light rays may be picked up and directed to the transducer by a system of mirrors, or separate transducers may be spaced around the lens in place of the pickup elements, in which case the transducers would all be connected to a common output.

Preferably, the array is made of bundles of optical fibers having their entrant faces radially spaced about the projection lens and their exit faces on a common surface facing the transducer. The arrangement may, alternatively, be regarded as a single furcate bundle having its legs radially spaced about the projection lens.

The use of plural pickup elements is also preferred because the absolute value of the reflected light is often relatively small compared to the value of the projection illumination, and plural elements produce a larger signal than a single element.

The optical pickup elements 20 which are placed around the projection lens 10 gather the light from various por tions of and from different viewing angles relative to the projection lens 10. The light signal is transmitted to the exit faces 28 of the bundle 32 so that the total light signal picked up by all the elements 20 is directed onto the photomultiplier tube 34. The signal produced by the photomultiplier tube 34 represents the average light intensity reflected from the various diiferent pickups and the value corresponds to the imaging light passing through the lens.

It is Within the scope of this invention to use a single pickup element, or a photoelectric transducer to sense the light reflected by the back surface of the projection lens. A single pickup element is particularly applicable for ordinary enlargers with full field illumination.

What is claimed is:

1. In a photographic projector of the type having a light source for illuminating a primary field and a projection lens for imaging the primary field upon a selected surface, the improvement comprising a plurality of elongated light transmitting members including entrant faces peripherally disposed around the back surface of the projection lens and adapted to receive the light passing through the field and reflected from the back surface of the lens, said elongated optical light transmitting members so constructed and arranged to conduct the light to a common point to thereby provide an averaging effect, detecting means disposed at said common point for producing a signal in response to the imaging light reflected from the surface of the projection lens and means generating a signal adapted for controlling the illumination.

2. A device as described in claim 1, in which, said light transmitting members comprise a furcate bundle of optical fibers.

References Cited in the file of this patent UNITED STATES PATENTS 2,122,750 Nicolson July 5, 1938 2,616,331 Pavelle Nov. 4, 1952 2,726,173 Martin Dec. 6, 1955 2,759,602 Baigent Aug. 21, 1956 2,804,550 Artzt Aug. 27, 1957 2,843,002 Allison July 15, 1958

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2122750 *Jul 5, 1934Jul 5, 1938Communications Patents IncLine television
US2616331 *Sep 6, 1945Nov 4, 1952Pavelle Color IncProjection printer
US2726173 *Apr 3, 1953Dec 6, 1955IttMethod and apparatus for measuring film thickness
US2759602 *Jul 17, 1952Aug 21, 1956Mattey Baigent GeorgeApparatus for detecting variation of surface characteristics of objects
US2804550 *Aug 14, 1952Aug 27, 1957Artzt MauriceAutomatic light control
US2843002 *Sep 16, 1953Jul 15, 1958William R AllisonDevice for inspecting the accuracy of curvature of optical material and lenses
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3188478 *Jan 11, 1962Jun 8, 1965Binks Melvin JPinhole detector optical system
US3198065 *Nov 21, 1960Aug 3, 1965Henry A BohmLight regulating means for projectors
US3245309 *Mar 4, 1963Apr 12, 1966Agfa AgLight-measuring structure for photographic devices
US3273274 *Jun 3, 1964Sep 20, 1966K G M Electronics LtdSelectively illuminated indicating devices
US3278739 *Jan 2, 1964Oct 11, 1966Bausch & LombIlluminator
US3418053 *Aug 28, 1964Dec 24, 1968Technicon InstrColorimeter flow cell
US3423594 *Mar 3, 1964Jan 21, 1969Galopin Anthony GPhotoelectric semiconductor device with optical fiber means coupling input signals to base
US3455637 *Aug 7, 1964Jul 15, 1969Giannini Controls CorpMethod and apparatus for measuring the opacity of sheet material
US3514882 *Jul 29, 1968Jun 2, 1970Gen ElectricLight controlling display apparatus responsive to fluid pressure
US3558895 *Nov 29, 1968Jan 26, 1971Bell & Howell CoLight sensor with optical light piping
US3564244 *Sep 13, 1966Feb 16, 1971Manuf Belge De Lampes Et De MaMeasuring device for thermoluminescent dosimetry including a diffusely reflecting body
US3623819 *Jul 22, 1969Nov 30, 1971Gossen & Co Gmbh PUniversally applicable photometer with adapters for reducing the measuring angle
US3625609 *Oct 13, 1969Dec 7, 1971Nord Photo Engineering IncCombined focusing and probe device for photographic enlargers
US3649118 *Apr 22, 1970Mar 14, 1972Fuji Photo Film Co LtdColor photography printing apparatus
US3672284 *Aug 4, 1970Jun 27, 1972Schwarz GerhardPhotographic camera
US3685901 *Mar 9, 1970Aug 22, 1972Crete Darrel RColor enlarger system
US3707715 *Jan 19, 1971Dec 26, 1972Olivetti & Co SpaData input device
US3869208 *Jan 10, 1973Mar 4, 1975Sartorius Membranfilter GmbhParticle-size spectrometers
US3982829 *Nov 18, 1974Sep 28, 1976Hoechst AktiengesellschaftExposure means for photocopying apparatus
US4188125 *Sep 2, 1977Feb 12, 1980Durst Ag Fabrik Fototechnischer ApparateApparatus for the determination of the color composition of the printing light in a photographic enlarger
US4394603 *Apr 2, 1981Jul 19, 1983Controlled Environment Systems Inc.Energy conserving automatic light output system
US4830446 *Nov 3, 1987May 16, 1989Photon Devices, Ltd.Production initializer for fiber optic document scanner
US4887190 *Oct 15, 1988Dec 12, 1989In Focis Devices Inc.High intensity fiber optic lighting system
US5042892 *Aug 3, 1990Aug 27, 1991David ChiuFiber optic light panel
US5143436 *Mar 6, 1991Sep 1, 1992The United States Of America As Represented By The United States Department Of EnergyRinglight for use in high radiation
US5317140 *Nov 24, 1992May 31, 1994Dunthorn David ISystem for optically determining the direction of an object
US6782184 *Dec 4, 2001Aug 24, 2004J.M. Canty, Inc.Modular insertion device for process illumination and viewing
WO1980000776A1 *Sep 26, 1979Apr 17, 1980Controlled Environment Syst InEnergy conserving automatic light output system
Classifications
U.S. Classification355/1, 355/68, 362/276, 250/227.28, 40/547, 362/552, 356/225
International ClassificationG03B21/20, G01J1/04, G01J1/42
Cooperative ClassificationG01J1/04, G03B21/20, G01J1/0425, G01J1/4219
European ClassificationG03B21/20, G01J1/04B5, G01J1/04, G01J1/42C1J